STM/STS Study on 4a×4aElectronic Charge Order of Superconducting Bi2Sr2CaCu2O8+δ

Momono, N.; Hashimoto, Akihiro; Kobatake, Yasuhiro; Oda, Masahiro; Ido, M.

doi:10.1143/jpsj.74.2400

Cited by 38 publications

(28 citation statements)

References 21 publications

(6 reference statements)

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“…3,6 Very recently the nondispersive 4a ϫ 4a charge order at T Ͻ T c was found to appear in heavily underdoped SC Bi2212. 11 The charge order is commensurate ͑4a ϫ 4a͒ and has an internal structure with a period of 4a /3ϫ 4a / 3, which is just like the electronic charge order reported by Hanaguri et al for lightly doped Na-CCOC. 1 The observation of almost the same charge order for both cuprates Na-CCOC and Bi2212 provides definite evidence that the nondispersive 4a ϫ 4a charge order develops on the Cu-O layer.…”

Section: Introductionsupporting

confidence: 69%

“…If the 4a ϫ 4a superstructure is due to some kind of lattice distortion, it is difficult to explain why the superstructure appears within a limited bias ͑energy͒ range, especially, associated with the gap size ⌬ 0 ; V s Շ⌬ 0 / e. Such a limitation of V s in observing the 4a ϫ 4a superstructure means that the superstructure is electronic in origin, that is, due to an electronic charge order, as has been claimed in many preceding studies. [1][2][3][9][10][11] The appearance of the 4a ϫ 4a charge order within the pairing gap implies that quasiparticles of the SC state and/or hole pairs will take part in causing the charge order.…”

Section: Shown Inmentioning

confidence: 99%

“…The 4a ϫ 4a charge order is likely to be dynamical in itself, and pinned down over regions with effective pinning centers. 11 To understand the nature of the nondispersive 4a ϫ 4a charge order, it is desirable to investigate the charge order on crystals with different doping levels and/or pinning centers of different natures.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Scanning tunneling microscopy and spectroscopy study of4a×4aelectronic charge order and the inhomogeneous pairing gap in superconductingBi2
Hashimoto
¹
,
Momono
²
,
Oda
³

et al. 2006
Phys. Rev. B
37
1
32
0
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We performed scanning tunneling microscopy and scanning tunneling spectroscopy ͑STS͒ measurements on underdoped Bi2212 crystals with doping levels p ϳ 0.11, ϳ0.13, and ϳ0.14 to examine the nature of the nondispersive 4a ϫ 4a charge order in the superconducting state at T Ӷ T c . The charge order appears conspicuously within the pairing gap, and low doping tends to favor the charge order. We point out the possibility that the 4a ϫ 4a charge order will be dynamical in itself, and pinned down over regions with effective pinning centers. The pinned 4a ϫ 4a charge order is closely related to the spatially inhomogeneous pairing gap structure, which has often been reported in STS measurements on high-T c cuprates.

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Section: Introductionsupporting

confidence: 69%

Section: Shown Inmentioning

confidence: 99%

See 1 more Smart Citation

Scanning tunneling microscopy and spectroscopy study of4a×4aelectronic charge order and the inhomogeneous pairing gap in superconductingBi2
Hashimoto
¹
,
Momono
²
,
Oda
³

et al. 2006
Phys. Rev. B
37
1
32
0
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“…It is also reasonable that almost homogeneous checkerboards appear in under doped cuprates where superconductivity disappears [13,15]; almost homogeneously AF moments presumably exist there. Inhomogeneous checkerboards can appear in under doped cuprates with rather low SC T c 's, when inhomogeneous AF moments are induced by disorder.…”

mentioning

confidence: 99%

Coexistence of a double-Qspin-density wave and a multi-Qpair-density wave in cuprate oxide superconductors

Ohkawa

2006

Phys. Rev. B

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Spatial 4a × 4a modulations, with a the lattice constant of CuO2 planes, or the so called checkerboards can arise from double-Q spin density wave (SDW) with Q1 = (±π/a, ±3π/4a) and Q2 = (±3π/4a, ±π/a). When multi-Q pair density wave, that is, the condensation of dγ-wave Cooper pairs with zero total momenta, ±2Q1, ±2Q2, ±4Q1, ±4Q2, and so on is induced by the SDW, gaps can have fine structures similar to those of the so called zero-temperature pseudogaps.PACS numbers: 74.20.-z, 75.10.-b, 74.90.+n, 71.10.-w High critical-temperature (high-T c ) superconductivity in cuprate oxides is an important and long standing issue since its discovery [1]. Many unconventional properties are observed in addition to high T c : the so called spin gap [2] or pseudogap above T c [3,4,5,6,7,8,9, 10], 4a × 4a spatial modulations called checkerboards, with a the lattice constant of CuO 2 planes, of local density of states (LDOS) around vortex cores [11], above T c [12], and below T c [13,14,15], the so called zero-temperature pseudogaps (ZTPG) [16], and so on. The issue cannot be settled unless not only high T c but also unconventional properties are explained within a theoretical framework.Since cuprates are highly anisotropic, thermal critical superconducting (SC) fluctuations, which would be divergent at nonzero T c in two dimensions [17], must play a role in the opening of pseudogaps. This issue is examined in another paper [18].The period of checkerboard modulations is independent of energies. Their amplitude depends on energies; it is only large in the gap region. When the modulating part is divided into symmetric and asymmetric ones with respect to the chemical potential, the symmetric one is larger than the asymmetric one [14]. Fine structures are observed in ZTPG [16]. It is difficult to explain these observations in terms of charge density wave (CDW). Several possible mechanisms have been proposed: Fermi surface nesting [19], valence-bond solids [20,21], pair density waves [22,23], hole-pair [19,24,25] or single-hole [19,20] Wigner solids, and Wigner supersolids [26,27]. The purpose of this Letter is to propose another mechanism: The spatial modulation of LDOS is due to spin density wave (SDW) and ZTPG is due to the coexistence of SDW and superconductivity or pair density waves induced by SDW.Cuprates with no dopings are Mott-Hubbard insulators, which exhibit antiferromagnetism. As dopings are increased, they exhibit the Mott-Hubbard transition or crossover and they becomes metals. High-T c superconductivity occurs in such a metallic phase. According to a previous theory [28], which is consistent with a combined one of Hubbard's [29] and Gutzwiller's [30] ones, a three-peak structure appears in the density of states; the so called Gutzwiller's quasiparticle band between the lower and upper Hubbard bands (LHB and UHB). This is confirmed by the single-site approximation (SSA) [31,32] that includes all the single-site terms or by the dynamical mean-filed theory (DMFT) [33]. The three-peak structure corresponds to the so cal...

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“…Recently, a similar charge order, whose amplitude is strongly sample-dependent, has been found in the SC state [3][4][5]. More interestingly, in samples which exhibit strong ∼ 4a 0 × 4a 0 charge orders at T T c , the spatial dependence of energy gap structure is very inhomogeneous in nanometer scale, and vice vasa.…”

Section: Resultsmentioning

confidence: 90%

STM studies on electronic charge order in the PG state of Bi2212

Liu

Takeyama

Ishikura

et al. 2007

Physica C: Superconductivity

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STM/STS Study on 4a×4aElectronic Charge Order of Superconducting Bi₂Sr₂CaCu₂O_8+δ

Cited by 38 publications

References 21 publications

Scanning tunneling microscopy and spectroscopy study of4a×4aelectronic charge order and the inhomogeneous pairing gap in superconductingBi2
Hashimoto
¹
,
Momono
²
,
Oda
³

et al. 2006
Phys. Rev. B
37
1
32
0
View full text Add to dashboard Cite

Scanning tunneling microscopy and spectroscopy study of4a×4aelectronic charge order and the inhomogeneous pairing gap in superconductingBi2
Hashimoto
¹
,
Momono
²
,
Oda
³

et al. 2006
Phys. Rev. B
37
1
32
0
View full text Add to dashboard Cite

Coexistence of a double-Qspin-density wave and a multi-Qpair-density wave in cuprate oxide superconductors

STM studies on electronic charge order in the PG state of Bi2212

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STM/STS Study on 4a×4aElectronic Charge Order of Superconducting Bi2Sr2CaCu2O8+δ

Cited by 38 publications

References 21 publications

Scanning tunneling microscopy and spectroscopy study of4a×4aelectronic charge order and the inhomogeneous pairing gap in superconductingBi2Hashimoto1, Momono2, Oda3 et al. 2006Phys. Rev. B371320View full textAdd to dashboardCite

Scanning tunneling microscopy and spectroscopy study of4a×4aelectronic charge order and the inhomogeneous pairing gap in superconductingBi2Hashimoto1, Momono2, Oda3 et al. 2006Phys. Rev. B371320View full textAdd to dashboardCite

Coexistence of a double-Qspin-density wave and a multi-Qpair-density wave in cuprate oxide superconductors

STM studies on electronic charge order in the PG state of Bi2212

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Product

Resources

About

STM/STS Study on 4a×4aElectronic Charge Order of Superconducting Bi₂Sr₂CaCu₂O_8+δ

Scanning tunneling microscopy and spectroscopy study of4a×4aelectronic charge order and the inhomogeneous pairing gap in superconductingBi2
Hashimoto
¹
,
Momono
²
,
Oda
³

et al. 2006
Phys. Rev. B
37
1
32
0
View full text Add to dashboard Cite

Scanning tunneling microscopy and spectroscopy study of4a×4aelectronic charge order and the inhomogeneous pairing gap in superconductingBi2
Hashimoto
¹
,
Momono
²
,
Oda
³

et al. 2006
Phys. Rev. B
37
1
32
0
View full text Add to dashboard Cite